Live attenuated COVID-19 vaccines: approaches to development and prospects for clinical use

Abstract

Although WHO declared an end to the pandemic, COVID-19 remains a significant public health concern worldwide. Modern vaccines often induce either only humoral or only cellular immunity. Furthermore, new emergent epidemiologically significant SARS-CoV-2 variants and their spread considerably reduce the effectiveness of preventive vaccination. Therefore, there is an urgent need to improve the existing vaccines against COVID-19. One of the promising approaches to the solution of the problem is creation of a "universal" vaccine that would have a cross-protective activity against different antigenic variants of the virus. In this respect, the development of live attenuated vaccine is of special interest, as it can activate not only humoral, but also cell-mediated components of immunity, providing long-term immune response and cross-protection against different variants of the virus. This review highlights the existing approaches to producing attenuated SARS-CoV-2 strains and gives an assessment of their prospects for clinical use. Some researchers use methods of genetic engineering and reverse genetics such as site-directed mutagenesis and codon deoptimization for virus attenuation. Others tend to use traditional approaches focusing on producing virus mutants through extended passaging in cell culture under selective conditions. The gained experience demonstrates great prospects for development of highly effective live-attenuated vaccine against COVID-19.